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Heat and Temperature Chapter 16 P. Sci. Unit 4 cont.
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What is Temperature? Particles (atoms and molecules) within a substance are constantly moving (kinetic energy) Particles (atoms and molecules) within a substance are constantly moving (kinetic energy) Temperature is the Temperature is the measure of the average kinetic energy in an object
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What is Temperature cont. As kinetic energy increases, temperature increases. As kinetic energy increases, temperature increases. Thermometers- expand as temperature increases and contracts as temperature decreases. Thermometers- expand as temperature increases and contracts as temperature decreases.
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Measuring Temperature Units for temperature can be Celsius (centigrade) Celsius (centigrade) Fahrenheit Fahrenheit Kelvin Kelvin
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Fahrenheit American scale – not used in science American scale – not used in science For Water For Water –Freezing point: 32°F –Boiling point: 212°F
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Celsius Also known as Centigrade Also known as Centigrade For water For water –Freezing point: 0°C –Boiling point: 100°C 1°C= about 2°F 1°C= about 2°F
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Kelvin SI unit to measure SI unit to measure temperature temperature 0 K is absolute zero= 0 K is absolute zero= -273.13 °C -273.13 °C Energy is minimal and Energy is minimal and cannot go any lower cannot go any lower
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Temperature Conversation K = °C + 273 K = °C + 273 °F = (9/5x °C) +32 °C = 5/9(°F-32) Convert 58 °C to K Convert 58 °C to K Convert 58 °C to °F Convert 58 °C to °F Convert 358 K to °C Convert 358 K to °C
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Energy Transfer Temperature is energy transferred as heat Temperature is energy transferred as heat Energy must move for heat to occur. Energy must move for heat to occur.
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Energy Transfer cont. Heat: transfer of energy between the particles of 2 objects due to temperature difference. Heat: transfer of energy between the particles of 2 objects due to temperature difference. Heat flows from high temperature (energy) to low temperature (energy) Heat flows from high temperature (energy) to low temperature (energy)
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Examples of energy transfer Freezing water for ice Freezing water for ice Dew evaporating in morning sunlight Dew evaporating in morning sunlight Heating water for a shower Heating water for a shower
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Types of Energy Transfer 1. Conduction: direct contact; 2 objects in contact are at unequal temperatures
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2. Convection: movement of warm fluids. Movement of the heated substance (liquid or gas) Convection Current: cycle of a heated fluid that rises, cools, and falls
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3. Radiation: no physical contact needed. Transfer of energy through electromagnetic waves (infrared, visible light, ultraviolet) No movement of matter –Example: standing in sunlight
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Which type of heat transfer is illustrated below? C
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Conductors Any material through which energy is easily Transferred. Any material through which energy is easily Transferred.
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Usually solid metals because their molecules are tightly packed. Usually solid metals because their molecules are tightly packed. Gases and liquids are poor conductors because the molecules are not as tightly packed together. Gases and liquids are poor conductors because the molecules are not as tightly packed together.
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Insulators Slow down Slow down heat transfer heat transfer Poor conductors Poor conductors Examples: rubber or wood Examples: rubber or wood
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Specific Heat The amount of energy needed to raise 1kg of a substance by 1 K The amount of energy needed to raise 1kg of a substance by 1 K Q= cmΔt Q= cmΔt – Q = heat – c = specific heat – m= mass – Δt= change in temperature Δt = final Temp – initial temp Δt = final Temp – initial temp –SI unit is Joules (J)
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Specific Heat Calculations Aluminum has a specific heat of 0.902 J/kg x °C. How much heat is lost when a piece of aluminum with a mass of 23.984 kg cools from a temperature of 415.0 °C to a temperature of 22.0 °C? Aluminum has a specific heat of 0.902 J/kg x °C. How much heat is lost when a piece of aluminum with a mass of 23.984 kg cools from a temperature of 415.0 °C to a temperature of 22.0 °C?
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Specific Heat Calculations 1. °C°C °C) 1. How much heat is required to warm 275 kg of water from 76 °C to 87 °C ? (specific heat of water is 4.179 J/g °C)
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Remember… Remember… – energy is always conserved. conserved. – Energy is transferred from higher temperatures to lower temperatures. – Insulation minimizes unwanted energy transfers in walls, attics, etc.
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Energy Transformations in Illustrations
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Bouncing Ball When dropping a ball it travels the following path where is the When dropping a ball it travels the following path where is the Kinetic energy is decreasing Kinetic energy is increasing Kinetic energy is the HIGHEST Kinetic energy is the LOWEST Potential energy is decreasing Potential energy is increasing Potential energy is the HIGHEST Potential energy is the LOWEST Both KE and PE present
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Pendulum A pendulum travels the following path where is the A pendulum travels the following path where is the Kinetic energy is decreasing Kinetic energy is increasing Kinetic energy is the HIGHEST Kinetic energy is the LOWEST Potential energy is decreasing Potential energy is increasing Potential energy is the HIGHEST Potential energy is the LOWEST Both KE and PE present
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Reading Specific Heat Tables Recall specific heat tells you how much energy is needed to increase the temperature of 1 gram by 1 degree. Recall specific heat tells you how much energy is needed to increase the temperature of 1 gram by 1 degree. –What substance takes the most energy to heat? –What substance take the least energy to heat? –What two substances listed make good conductors? –What two substances make good insulators?
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K = °C + 273 °F = (9/5x °C) +32 °C = 5/9(°F-32) Kinetic Energy =1/2 (mass x velocity 2 ) KE = ½ m v 2 Potential Energy = mass x gravity x height PE = m g h g = 9.8 m/s 2 Heat = mass x specific heat x change in temp Q = m c Δt
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Review 1. What is temperature? 2. Name the 3 different scales with which temperature is measured. 3. Convert 51°C to Kelvin.
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4. Convert 324K to Celsius. 5. Name 3 methods of energy transfer and explain how they work. 6. Explain the difference between conductors and insulators and insulators
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Unit 4 Equations K = °C + 273 °F = (9/5x °C) +32 °C = 5/9(°F-32) Kinetic Energy =1/2 (mass x velocity 2 ) KE = ½ m v 2 Potential Energy = mass x gravity x height PE = m g h g = 9.8 m/s 2 Heat = mass x specific heat x change in temp Q = m c Δt Δt = final temp – initial temp
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